Cement & concrete
0.02-1.25 usd/kgConcrete is a complex composite, which can contain all manner of material, including cement, plant, wood, metal and plastic. Using very low cost ingredients, such as industrial by-products, makes it a cost-effective material for large-scale projects and structures.
Ordinary concrete contains a mix of Portland cement (OPC), aggregates and sand. When mixed with water, the cement forms a paste that fills the voids between the sand and aggregate, binding them together. The hardening process, which is the result of a chemical reaction with water, is known as hydration.
Regular Portland cement is made by cooking limestone, sand and clay in kilns at 1,450 degC. Even though it has relatively low kgCO2/kg, it is consumed in such huge volumes that it accounts for around 8% of global CO2 emissions according to The World Economic Forum. Around 50-60% the CO2 emissions come from the limestone as it decomposes in the kiln to form reactive lime (reactive calcium oxide, RCC). The remainder of the CO2 comes from burning fossil fuels to heat the kiln. It is not practical to achieve the high temperatures required for the kiln using electricity, which makes it difficult to reduce the carbon footprint using current technology.
Cement-based building products and concrete are available in eight basic forms, each with its own unique quantities and advantages:
– Ready-mixed, which includes cement, water, sand and aggregates. It is used for casting and pouring.
– Pre-cast concrete, which is produced in a factory and includes everything from masonry blocks and decorative trim to very large reinforced concrete structures.
– Cement-based products that are not strictly classed as concrete, but share many of the same qualities. They are typically a mix of cement, water, sand and perhaps lime. Examples include mortar, render, terrazzo and grout.
– Cement-based products mixed with special fibres or additives to create products such as roof tiles, countertops and construction boards.
– Polymer concrete uses plastic to replace the cement, either partially or entirely. In this case, the concrete hardness through a process of polymerisation. Polymer concrete is typically much more expensive, but has some desirable benefits for certain applications.
– Biocement is made with calcium carbonate (CaCO3) produced by microorganisms and is being explored as a sustainable alternative to Portland cement. Through a process of microbiologically induced calcium carbonate precipitation (MICP), microorganisms react with chemical components to produce minerals suitable as binding agents. As well as having potential as a building material, it is used for reinforcing soils, such as is important for transport infrastructure and sea defences. Compared to OPC it can reduce carbon emissions by up to 90%.
– LC3 cement has a reduced carbon footprint (30-40%) as a result of partially substituting (20-70%) the clinker used in production with calcined clay and limestone. The reduction is the result of reducing the firing temperature and avoiding the decomposition of limestone, which is responsible for a significant proportion of the CO2 of cement production. Clay is calcined (heated to around 800 degC, as opposed to 1,450 degC for regular cement) to make it suitable. It is widely available and compatible with modern cement manufacturing processes. While clinker is a waste product from burning coal and steel furnaces, it is not always available close to the cement factories, and the processes that generate it have come into question over sustainability concerns.
– Low-carbon cement (green cement) is produced using various techniques such as with renewable energy (fuel from biomass, for example); using Portland Limestone Cements (PLCs) and supplementary cementitious materials (SCMs) in the mix; and with carbon capture, such as harnessing industrial CO2 emissions in the production process, or injecting CO2 back into concrete to strengthen it.
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Fibre reinforced concrete (FRC) combines the bulk compressive strength of concrete with the tensile strength of fibres, such as made from steel, polypropylene (PP), AR-glass, jute, hemp and sisal. While manufactured fibres have higher mechanical properties, they also tend to be more expensive and have a greater environmental impact, compared to locally available natural alternatives.
Even with very low dosage, in the region of 0.5-2%, there are significant improvements in mechanical properties: up to around 20% improvement in compression strength and 30% in tensile strength. Fibre reinforcement can be used with most types of concrete, where an uplift in tensile properties is advantageous, and a reduction in the number and size of cracks desirable. These examples are normal to high strength concrete: C50 and C60. While there are many advantages to using FRC, they are more expensive than unreinforced concrete, require carefully controlled mixing, and can affect fluidity (which is detrimental to pouring and casting).